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土壤压实及有机质对其影响的研究进展 总被引:1,自引:1,他引:1
《土壤通报》2019,(5):1253-1260
压实导致土壤板结的发生、与土壤团聚体的形成和破坏直接相关,而土壤的孔隙状况和水、气、热等条件改变在影响作物生长的同时,也会带来水土流失、碳氮温室气体排放等环境问题。在当今农业现代化进程加快、机械化水平提高的背景下,压实所引发的土壤板结问题愈益引起人们关注。本文在对土壤压实过程及其压缩曲线、表征参数等进行介绍的基础上,对近年来土壤压实过程及其影响因素方面的研究进展进行梳理,从提高土壤肥力、防治土壤板结的角度重点阐述了有机质改良土壤压实性状的效果及其作用机制,并对这一研究领域今后的发展趋势做了展望;研究认为在减少农业机械作业对农田压实次数和压实强度的前提下,提高土壤有机质含量、实行合理耕作仍然是我国今后改良土壤机械物理性质、培肥土壤和防止土壤板结的主要途径。 相似文献
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传统的土壤压实风险评估方法是基于土壤的先期固结压力理论,以机械的接地压力与土壤先期固结压力间关系作为判断依据,缺少针对集约化稻作“湿耕烂种”等生产场景中由定量机械压实造成的土壤结构破坏程度的评价方法和依据。为研究适合中国稻作特色,可以定量预测机械压实危害程度的压实容重预测模型,该研究基于土壤的回弹指数和压缩指数推导出土壤压实容重预测模型,以适用于集约化生产条件下稻田土壤机械压实预测。采用调控原状土含水率的单轴压缩试验法分别构建了土壤初始容重、初始含水率与弹性压缩模量、塑性压缩模量和先期固结压力之间的传递函数,然后基于典型机型的田间原位平板下陷试验验证所建模型的可靠性和实用性。结果表明,基于单轴压缩试验法构建的各传递函数拟合决定系数大于0.95。将各传递函数模型所得的弹性压缩模量、塑性压缩模量和先期固结压力输入土壤压实容重模型预测的压实后的土壤容重与实测值的相对误差小于5%。可见,该研究设计的土壤压实预测模型能够准确量化受机械压实情况下土壤容重的变化量,而土壤传递函数法能为构建和应用区域性农业土壤的压实模型提供便利。研究可为集约化生产条件下稻作“湿耕烂种”等生产场景中由定量机械压实造成的... 相似文献
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采用Gompertz函数的水稻土压缩特性研究 总被引:4,自引:1,他引:3
土壤压实模型是预测压实破坏的常用方法,但土壤压实模型的应用常因输入参数(土壤压缩特性及其与不同土壤物理性质之间的关系)的缺乏而受到限制。为定量地评价土壤水力学性质和土壤结构对土壤压缩特性的影响,该文利用土壤固结仪对25种不同含水率和容重的重塑土样进行单轴压缩试验,并采用Gompertz函数对试验数据进行拟合以获取土样的回弹指数、压缩指数和先期固结压力。试验结果表明,Gompertz函数对水稻土试验数据的拟合效果较优,决定系数为0.991~0.999。水稻土回弹指数为0.003~0.138,与容重呈负相关,与含水率呈正相关。水稻土压缩指数为0.115~0.839,与容重呈负相关,与含水率呈二次多项式关系。水稻土先期固结压力为33~127k Pa,与容重呈正相关,与含水率呈负相关。该研究建立的土壤压缩特性与含水率和容重之间的传递函数,可用于大尺度范围内水稻土压缩特性的预测;同时这些传递函数可作为土壤压实模型的输入参数,用于农业机械作业引起的压实破坏的量化和土壤压实风险的评估。 相似文献
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大中小型拖拉机压实对土壤坚实度和大豆产量的影响 总被引:4,自引:3,他引:1
探讨农业机械压实对土壤坚实度和产量的影响规律,对改善作物生产环境、促进农业机械化向质量型转变具有重要意义。以东北典型黑土区耕地土壤为研究对象,依照随机区组试验原理,选择大、中、小3种型号拖拉机进行6种压实处理,同型拖拉机相同压实次数试验重复3次,采用PV6.08型贯穿阻力仪测量压实轮辙截面土壤坚实度。试验结果表明:土壤坚实度随压实次数增加而逐渐递增,3种拖拉机压实测试截面浅层均出现明显压实核,且压实核内土壤坚实度随压实次数增加而逐渐增大,CASE-210型拖拉机压实对表层土壤坚实度影响程度和范围最大,压实12次时压实核处土壤坚实度达4.0 MPa,JD-280型拖拉机对深层土壤压实影响程度和范围最大,在65~80 cm的土壤深层坚实度的峰值达3.2 MPa;拖拉机压实均导致大豆产量降低,CASE-210、JD-904和JD-280拖拉机压实12次时大豆产量分别降低了21.24%、18.15%和12.38%。 相似文献
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矿区机械压实对土壤孔隙特性影响的研究进展 总被引:4,自引:0,他引:4
在矿区开采和复垦过程中大型机械的使用产生了土壤压实,并严重扰动了土壤内部结构,导致土壤孔隙数量减少,连通性和渗水能力下降,土壤孔隙作为土壤水气交换的重要场所决定着土壤水分和空气状况,进而影响复垦土壤质量与肥力。为探究矿区机械压实作用对土壤孔隙的影响,系统梳理了矿区机械压实作用下土壤孔隙的获取和表征方法,对农业机械压实相关研究进行了简单归纳,在此基础之上阐述了矿区机械压实对土壤孔隙影响的研究进展,总结了当前研究存在的问题,并提出今后在探究矿区机械压实对土壤孔隙特性影响时应创新压实土壤孔隙的定量表征方法,重视机械压实对土壤孔隙特性影响机理的考究,以期为改善矿区土地复垦效果提供理论指导。 相似文献
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均质土壤承压下陷模型改进及验证 总被引:1,自引:1,他引:0
针对传统土壤承压模型依赖拟合原位承载试验曲线的复杂性或建立在土壤力学参数基础上的预测模型的理想化等问题,该文提出一种改进的土壤承压下陷模型。依据地面力学和土壤力学相关理论将土壤承压力学模型分3类进行简要介绍,分析其各自特点和参数意义。结合土壤承压极限理论的指数形式,提出改进的土壤承压模型。利用庄继德等人的相关试验研究结果进行验证,结果表明砂性土、水稻土的土壤承压下陷计算预测曲线与实际拟合曲线吻合度较好,其中砂土试验的Bekker下陷曲线与改进模型计算所得曲线的决定系数R2为0.9998;利用Bekker文献中的黏性土试验参数数据进行验证,计算所得土壤极限应力值与相应位置贝氏方程拟合应力值误差在5%~21%之间,土壤变形指数求解值与实际值误差在7%~36%之间。该模型普适性、准确性较强,可在测得土体基本力学参数的基础上预测载荷下陷曲线,为研究车辆行驶下陷提供参考。 相似文献
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基于修正介电常数模型的煤矿区复垦土壤压实评价 总被引:1,自引:0,他引:1
模拟复垦机械对试验区土壤进行不同程度的压实,在探地雷达获取土壤介电常数的基础上,检验并修正了4种经典复合介电常数模型,并结合野外试验对修正后的模型通用性进行了验证。结果表明,土壤介电常数与土壤压实指标(土壤紧实度、容重、孔隙率等)相关系数89%,可以表征土壤压实状况;原有复合介电常数模型虽然存在误差不能直接使用,但模型计算值与实测值相关系数0.99,修正后二者拟合误差1%;在野外试验中,基于修正后的介电常数模型反算的土壤压实指标(容重、孔隙率)与实验室测量值误差率5%,通用性较好。表明在科学布设测线以保证探地雷达准确获取土壤介电常数的前提下,可以通过修正后的复合介电常数模型对煤矿区复垦土壤压实状况进行全面客观的评价。 相似文献
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城市化过程对土壤资源影响研究进展 总被引:2,自引:0,他引:2
世界范围内的快速城市化过程对土壤资源的质与量都产生了深刻影响.作为一种不可再生性自然资源,土壤在我国快速城市化过程中的强烈人为活动影响下发生功能上的转化、弱化甚至消失.城市及其周边地区的土壤景观、各种土壤过程都明显异于传统的土壤质量演变规律.与农业生态系统相比,城市生态系统更加复杂,城市化过程中土壤演变研究的挑战性也更大.深入开展城市化过程中土壤质、量响应及其生态环境效应的系统研究意义重大. 相似文献
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Review of modelling crop growth, movement of water and chemicals in relation to topsoil and subsoil compaction 总被引:4,自引:0,他引:4
Soil compaction influences crop growth, movement of water and chemicals in numerous ways. Mathematical modelling contributes to better understanding of the complex and variable effects. This paper reviews models for simulating topsoil and subsoil compaction effects. The need for including both topsoil and subsoil compaction results from still increasing compactive effect of vehicular pressure which penetrates more and more into the subsoil and which is very persistent. The models vary widely in their conceptual approach, degree of complexity, input parameters and output presentation. Mechanistic and deterministic models were most frequently used. To characterise soil compactness, the models use bulk density and/or penetration resistance and water content data. In most models root growth is predicted as a function of mechanical impedance and water status of soil and crop yield—from interactions of soil water and plant transpiration and assimilation. Models for predicting movement of water and chemicals are based on the Darcy/Richards one-dimensional flow equation. The effect of soil compaction is considered by changing hydraulic conductivity, water retention and root growth. The models available allow assessment of the effects of topsoil and subsoil compaction on crop yield, vertical root distribution, chemical movement and soil erosion. The performance of some models was improved by considering macro-porosity and strength discontinuity (spatial and temporal variability of material parameters). Scarcity of experimental data on the heterogeneity is a constraint in modelling the effects of soil compaction. Suitability of most models was determined under given site conditions. Few of the models (i.e. SIBIL and SIMWASER) were found to be satisfactory in modelling the effect of soil compaction on soil water dynamics and crop growth under different climate and soil conditions. 相似文献
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S. Seladji P. Cosenza A. Tabbagh J. Ranger G. Richard 《European Journal of Soil Science》2010,61(6):1043-1055
Among the geophysical tools used in soil science, electrical methods are considered as potentially useful to characterize soil compaction intensity. A laboratory investigation was undertaken on agricultural and forest soils in order to study the impact of compaction on bulk soil electrical resistivity. Samples taken from four different types of loamy soils were compacted at three bulk densities (1.1, 1.3 and 1.6 g cm−3). Bulk soil resistivity was measured at each compacted state for gravimetric water contents ranging from 0.10 to 0.50 g g−1. A specific experimental procedure allowed the control of the water‐filling of the intra‐aggregate pores and the inter‐aggregate pores. Soil resistivity decreased significantly with increase in density and typically for gravimetric water contents less than 0.25 g g−1. The decrease was more pronounced for the drier soils, indicating the strong impact of the surface conductance, especially in agricultural soils. The experimental data were in good agreement with simulated values given by the petro‐physical model of Waxman‐Smits (1968) , at least for water saturation greater than 0.3. The analysis of the petro‐physical parameters derived from the experimental data suggested that: (i) the electrical tortuosity of the loamy agricultural soil was significantly affected by compaction and (ii) the forest soil had a singular microstructure from an electrical point of view and had isolated conductive zones associated with clay embedded in a poorly conductive medium comprised mainly of soil solution and quartz grains. Our results provide the phenomenological basis for assessing, in the field, the relationship between soil electrical resistivity and compaction intensity. 相似文献
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Protecting soil structure against compaction—proposed solutions to safeguard agricultural soils To safeguard the ecological soil functions and the functions linked to human activities, measures against harmful changes to the soil are required, in line with the precautionary principle. The German Federal Soil Protection Act sets obligations for precaution in agricultural land use and, if harmful changes to the soil are foreseeable, measures for averting a danger. The results of a research project of the Federal Environmental Agency show that it is possible to describe an impairment of the soil structure, using methods of soil analysis. But this as a sole information would not qualify for the identification of harmful changes to the soil in the context of the Soil Protection Act, which requires an assessment of the severity of disruption of soil functions and the respective subject of protection. This would make additional soil investigations on site mandatory. Approaches in agricultural engineering and soil physics have introduced procedures to preserve the soil structure, in accordance with the precautionary principle. But these procedures have different goals and different ranges of application and hence offer partial solutions to safeguard against soil compaction. The assessment model of “trafficability by measuring the rut depth” provides information about the compaction status of the soil under applied conditions for farming gear, without providing detailed information about affected soil layers. The soil‐physical model of classifying soils into “risk classes for harmful soil compaction” focuses on the relationship between topsoil compaction and crop yields. The soil‐physical models “precompression stress” and “loading ratio” provide information for the assessment of subsoil compaction and a prognosis of a possible impairment of the soil structure at the water content of field capacity. It is necessary to validate the individual models with additional regional data about soil structure before a final assessment of the prognoses is made. 相似文献
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A method for predicting soil susceptibility to the compaction of surface layers as a function of water content and bulk density 总被引:2,自引:0,他引:2
K. Saffih-Hdadi P. Dfossez G. Richard Y.-J. Cui A.-M. Tang V. Chaplain 《Soil & Tillage Research》2009,105(1):96-103
Identifying the vulnerability of soils to compaction damage is becoming an increasingly important issue when planning and performing farming operations. Soil compaction models are efficient tools for predicting soil compaction due to agricultural field traffic. Most of these models require knowledge of the stress/strain relationship and of mechanical parameters and their variations as a function of different physical properties. Since soil compaction depends on the soil's water content, bulk density and texture, good understanding of the relations between them is essential to define suitable farming strategies according to climatic changes. In this work we propose a new pedotransfer function for 10 representative French soils collected from cultivated fields, a vineyard and forests. We investigate the relationship between soil mechanical properties, easily measurable soil properties, water content and bulk density. Confined compression tests were performed on remoulded soils of a large range of textures at different initial bulk densities and water contents. The use of remolded samples allowed us to examine a wide range of initial conditions with low measurement variability. Good linear regression was obtained between soil precompression stress, the compression index, initial water content, initial bulk density and soil texture. The higher the clay content, the higher the soil's capacity to bear greater stresses at higher initial water contents without severe compaction. Initial water content plays an important role in clayey and loamy soils. In contrast, for sandy soils, mechanical parameters were less dependent on initial water content but more related to initial bulk density. These pedotransfer functions are expected to hold for the soils of tilled surface layers, but further measurements on intact samples are needed to test their validity. 相似文献
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Thomas Keller Pauline Dfossez Peter Weisskopf Johan Arvidsson Guy Richard 《Soil & Tillage Research》2007,93(2):391-411
Soil compaction is one of the most important factors responsible for soil physical degradation. Soil compaction models are important tools for controlling traffic-induced soil compaction in agriculture. A two-dimensional model for calculation of soil stresses and soil compaction due to agricultural field traffic is presented. It is written as a spreadsheet that is easy to use and therefore intended for use not only by experts in soil mechanics, but also by e.g. agricultural advisers. The model allows for a realistic prediction of the contact area and the stress distribution in the contact area from readily available tyre parameters. It is possible to simulate the passage of several machines, including e.g. tractors with dual wheels and trailers with tandem wheels. The model is based on analytical equations for stress propagation in soil. The load is applied incrementally, thus keeping the strains small for each increment. Several stress–strain relationships describing the compressive behaviour of agricultural soils are incorporated. Mechanical properties of soil can be estimated by means of pedo-transfer functions. The model includes two options for calculation of vertical displacement and rut depth, either from volumetric strains only or from both volumetric and shear strains. We show in examples that the model provides satisfactory predictions of stress propagation and changes in bulk density. However, computation results of soil deformation strongly depend on soil mechanical properties that are labour-intensive to measure and difficult to estimate and thus not readily available. Therefore, prediction of deformation might not be easily handled in practice. The model presented is called SoilFlex, because it is a soil compaction model that is flexible in terms of the model inputs, the constitutive equations describing the stress–strain relationships and the model outputs. 相似文献
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根系水质模型中土壤与作物参数优化及其不确定性评价 总被引:9,自引:5,他引:4
农业系统模型参数优化存在很高的不确定性,是模型应用研究的重点和难点。该研究利用自动优化程序PEST(parameter estimation software)对根系水质模型(root zone water quality model,RZWQM)中土壤参数(土壤水力学参数和根系生长参数)和作物遗传参数进行了优化,结果表明PEST优化模拟结果明显优于传统试错法的校正结果,且具有较高的参数优化效率。模型参数优化不确定性评价表明校正数据和参数初始值的选择、土壤水力学参数估算方法、不同类型参数间的相互作用以及优化目标方程(误差来源计算)都明显影响模型模拟结果。以上过程中土壤水力学参数优化值差异较小,但其土壤水分特征曲线却明显不同。通过以上评价分析提高了RZWQM相关参数优化结果的可靠性及其模拟功能,降低了模型参数优化的不确定性,为PEST优化其他模型参数提供了重要支持。 相似文献
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Elham Shahrayini Mahboobeh Fallah Mahmoud Shabanpour Saeid Saadat 《Archives of Agronomy and Soil Science》2018,64(10):1329-1340
Inappropriate crop management and long-term use of heavy agricultural equipment can lead to soil compaction. On the other hand, soil and water salinity causes reduction in the plant yield in addition to adverse effects on plants tolerance to the various stresses. The aim of this study was to investigate the interaction between soil compaction and salinity on the macronutrients uptake and wheat yield as well as its agronomic traits. The pot experiment was carried out on the loamy soil in a completely randomized block design with three replications. The treatments consisted of two salinity types (saline, EC = 6 dS/m and non-saline soil) and five levels of compaction; control, 5%, 10%, 15% and 20%. The results showed that soil compaction had significant effect on the amount of N, P and K in wheat grain, so that the uptake of N, P and K by grain has been decreased by increasing the compaction level of soil. Soil salinity had significant effect on N, P and K content in grain that the content of N, P and K has been diminished in the saline treatments compared to non-saline treatments. Results on the agronomic traits and yield of wheat also revealed that soil compaction and salinity had significant effect (p < 0.01) on straw weight, number of ears, number of grain, and thousand grain weight which caused reduction in these parameters. The interaction between compaction and salinity had only significant correlation (p < 0.01) with thousand grain weight leading to the decrement of thousand grain weight with increasing compaction levels, particularly in the saline treatment. 相似文献
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Soil compaction by agricultural machines can have adverse effects on crop production and the environment. Different models based on the Finite Element Method have been proposed to calculate soil compaction intensity as a function of vehicle and soil properties. One problem when modelling soil compaction due to traffic is the estimation of vertical stress distribution at the soil surface, as the vertical stress is inhomogeneous (non-uniform) and depends on soil and tyre properties. However, uniform stress distribution at the soil/tyre interface is used to predict the compaction of cultivated soils in most FEM compaction models. We propose a new approach to numerically model vertical stress distribution perpendicular to the driving direction at the soil/tyre interface, employing the FEM models of PLAXIS code. The approach consists of a beam (characterised by its geometric dimensions and flexural rigidity) introduced at the soil surface and loaded with a uniform stress with the aim to simulate the action of a wheel at the soil surface. Different shapes of stress distribution are then obtained numerically at the soil surface by varying the flexural rigidity of the beam and the mechanical parameters of the soil. PLAXIS simulations show that the soil type (soil texture) modifies the shape of the stress distribution at the edges of the contact interface: a parabolic form is obtained for sand, whereas a U-shaped is obtained for clay. The flexural rigidity of the beam changes the shape of distribution which varies from a homogenous (uniform) to an inhomogeneous distribution (parabolic or U-shaped distribution). These results agree with the measurements of stress distributions for different soils in the literature. We compared simulations of bulk density using PLAXIS to measurement data from compaction tests on a loamy soil. The results show that simulations are improved when using a U-shaped vertical stress distribution which replaces a homogenous one. Therefore, the use of a beam (cylinder) with various flexural rigidities at the soil surface can be used to generate the appropriate distribution of vertical stress for soil compaction modelling during traffic. 相似文献
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Growth and symbiotic activity of legumes are reduced by high soil compaction and mediated by Nod factors (LCO, lipo-chitooligosaccharides) application. Our objective was to assess the combined effects of soil compaction and Nod factors application on growth and symbiotic activity of pea. The experiment was two factorial and included soil compaction (1.30 g cm−3 – not compacted (control) and 1.55 g cm−3 – compacted soil), and Nod factors concentration (control without addition of Nod factors and use of 260 nM Nod solution) for each soil compaction. The soil (Haplic Luvisol) was packed into pots, pea (Pisum sativum L.) seeds were soaked with Nod factors solution or water and then plants were grown for 46 days. This study has shown that soil compaction and treatments of pea seeds with Nod factors influenced pea growth and symbiotic activity. Soil compaction significantly reduced pea growth parameters, namely plant height, dry mass, leaf area, root mass and root length and symbiotic parameters, namely mass of nodules, dry mass of an individual nodule, nitrogenase activity and total nitrogen content in plant in comparison to the non-compacted treatment. Treatment of seeds with Nod factors generally improved nearly all of the above parameters. Nitrogenase activity per pot and total plant nitrogen content were significantly reduced by soil compaction and increased by application of Nod factors in plants grown in not compacted soil. Our results demonstrate that increased symbiotic activity resulting from Nod factors addition may mitigate adverse effect of soil compaction on plant growth. 相似文献